Abstract
Healthy brain function depends on the finely tuned spatial and temporal delivery of blood-borne nutrients to active neurons via the vast, dense capillary network. Here, using in vivo imaging in anesthetized mice, we reveal that brain capillary endothelial cells control blood flow through a hierarchy of IP(3) receptor-mediated Ca(2+) events, ranging from small, subsecond protoevents, reflecting Ca(2+) release through a small number of channels, to high-amplitude, sustained (up to ~1 min) compound events mediated by large clusters of channels. These frequent (~5000 events/s per microliter of cortex) Ca(2+) signals are driven by neuronal activity, which engages G(q) protein-coupled receptor signaling, and are enhanced by Ca(2+) entry through TRPV4 channels. The resulting Ca(2+)-dependent synthesis of nitric oxide increases local blood flow selectively through affected capillary branches, providing a mechanism for high-resolution control of blood flow to small clusters of neurons.